Refrigeration – Processes – Defrosting or frost inhibiting
Reexamination Certificate
1999-01-29
2001-01-09
Tanner, Harry B. (Department: 3744)
Refrigeration
Processes
Defrosting or frost inhibiting
C062S277000, C062S185000
Reexamination Certificate
active
06170270
ABSTRACT:
FIELD OF THE INVENTION
The invention relates generally to a refrigeration system that uses a warm liquid defrost cycle. More particularly, the invention relates to a refrigeration system that uses liquid-to-liquid heat transfer to heat the coolant that will be used for the warm liquid defrost cycle.
BACKGROUND OF THE INVENTION
Present day food stores such as supermarkets and convenience stores typically use relatively high capacity refrigeration systems to keep their refrigerated and frozen food products cold. The two most common types of refrigeration systems may be generally designated as direct expansion systems and secondary coolant systems. In direct expansion systems, a two-phase, vapor-compression refrigeration loop is used which normally includes an evaporator positioned inside the refrigerated space that absorbs heat from the space, thereby cooling the space to the desired temperature. In secondary coolant systems, a primary refrigeration loop and a secondary refrigeration loop are used in conjunction to cool the refrigerated space. The primary loop of the system is typically a vapor-compression system similar to that used in direct expansion systems and usually comprises a compressor, condenser, receiver, and an expansion device. The secondary loop is typically a single-phase system and comprises a pump and a heat exchanger that is disposed within the refrigerated space to absorb heat therefrom. The two loops of secondary coolant systems thermally communicate with each other through a chiller which provides for heat transfer between the primary and secondary loops.
Currently, there is a trend toward use of secondary coolant systems rather than direct expansion systems in that the amounts of primary refrigerant used in the refrigerated space can be minimized when a secondary coolant system is used, increasing safety to personnel and customers that interact with the refrigerated space. In addition, secondary coolant systems provide the advantage of improving temperature stability and humidity within the refrigerated space.
As is well known in the art, moisture contained within the refrigerated space condenses on the heat exchanger used in the refrigerated space and freezes thereon to form frost. This frost greatly decreases the cooling efficiency of the refrigeration system and, if left to accumulate, can even block the flow of air through the evaporator or heat exchanger to diminish the heat exchange capacity of the refrigeration system. Several methods of removing this frost, known as defrosting, have been developed in the refrigeration arts. The simplest method is so called “off-cycle” defrost in which the refrigeration cycle is simply discontinued and the heat of the surrounding air meets the frost. In another method, the evaporator or heat exchanger is electrically heated to melt the frost. In direct expansion systems, typically the hot gas of the refrigerant discharged by the compressor is used to melt the frost. In yet another method, the secondary coolant system is defrosted by passing warm coolant through the refrigerated space heat exchanger for a predetermined period of time and/or temperature, so that the frost formed thereon melts and drains away. Of these several methods, liquid defrost is generally preferred in the art for several reasons. First, warm liquid defrost is safer than electrical and hot gas defrost in that it is less stressful on the refrigeration system. In addition, warm liquid defrost is more efficient than electrical and hot gas defrost and therefore does not result in a large degree of warming of the refrigerated space. This avoids food spoilage and also increases system efficiency in that a large degree of cooling is not necessary to bring the refrigerated space back to its standard operating temperature.
The most common methods of heating the liquid supplied to the coils located in the refrigeration space typically utilize the hot gas of the refrigeration system that is discharged by compressor. In particular, the hot gas from the compressor is diverted to a gas-to-liquid heat exchanger, often referred to as a heat reclamation tank, in fluid communication with the secondary coolant in which the coolant is heated so it then can be delivered to the refrigerated space heat exchanger.
Although typically providing enough heat energy to adequately defrost the coils of the refrigerated space evaporator or heat exchanger, usage of gas-to-liquid heat exchange presents several disadvantages. Specifically, gas has a relatively low coefficient of heat transfer in comparison to liquid. Due to this relatively low coefficient of heat transfer, the defrost liquid often must be prepared in advance of the defrost cycle to ensure adequate heating of the refrigeration space coils. Accordingly, defrost in many systems cannot be had “on demand.” Moreover, the relatively low coefficient of heat transfer of the gas mandates relatively large heat transfer surface areas between the gas side and the liquid side of the heat reclamation tank or other heat exchanger. To provide this large heat transfer surface area, the heat reclamation tank or other heat exchanger typically must be large in size and, consequently, is quite expensive. Additionally, usage of heat reclamation tanks often requires the usage of other expensive equipment such as valves and control systems which are used to control operation of the reclamation tank.
From the above, it can be appreciated that it would be desirable to have a refrigeration system which utilizes warm liquid defrosting of the refrigerated space coils which is not dependent upon the hot discharge gas from the compressor and gas-to-liquid heat exchange.
SUMMARY OF THE INVENTION
Briefly described, the present invention comprises a warm liquid defrost refrigeration system comprising a primary refrigeration loop including a compressor, a condenser, an expansion device, and a first side of a chiller, and secondary refrigeration loop including a pump, a refrigerated space heat exchanger, and a second side of the chiller. In that both the primary refrigeration loop and the secondary refrigeration loop connect to the chiller, the primary and secondary refrigeration loops are in thermal communication with each other.
The refrigeration system further includes a defrost heat exchanger having a hot side and a cold side. The hot side of the defrost heat exchanger is connected to the primary refrigeration loop between the condenser and the expansion device such that liquid refrigerant can flow from the condenser or receiver through the hot side of the defrost heat exchanger. The cold side of the defrost heat exchanger is connected to the secondary refrigeration loop at a point downstream of the pump such that coolant can be selectively transported from the pump through the cold side of the defrost heat exchanger. The cold side of the defrost heat exchanger is also connected to the refrigerated space heat exchanger such that the cold side of the defrost heat exchanger can be selectively placed in fluid communication with the refrigerated space heat exchanger during defrost cycles.
When a defrost cycle is operated, coolant from the secondary refrigeration system flows through the cold side of the defrost heat exchanger, is heated by the liquid refrigerant flowing through the hot side of the defrost heat exchanger, and then is transported to the refrigerated space heat exchanger to melt any frost formed on the refrigerated space heat exchanger. Operating in this manner, the refrigeration system presents many advantages over conventional refrigeration systems in use today. In particular, the liquid-to-liquid heat transfer provided by the defrost heat exchanger saves space and decreases cost of the refrigeration system by reducing the heat transfer surface area needed to heat the coolant for defrost and by sub-cooling the liquid refrigerant before expansion in the primary loop.
The objects, features, and advantages of this invention will become more apparent upon reading the following specification, when taken in conjunction with the accompanyi
Arshansky Yakov
Hinde David K.
Delaware Capital Formation Inc.
Tanner Harry B.
Thomas Kayden Horstemeyer & Risley
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